DOCSLIB.ORG

Antifreeze Proteins Govern the Precipitation of Trehalose in a Freezing-Avoiding Insect at Low Temperature

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Antifreeze Proteins Govern the Precipitation of Trehalose in a Freezing-Avoiding Insect at Low Temperature Antifreeze proteins govern the precipitation of trehalose in a freezing-avoiding insect at low temperature Xin Wena,b,1, Sen Wanga,2, John G. Dumanc, Josh Fnu Arifina, Vonny Juwitaa, William A. Goddard IIIb, Alejandra Riosa,b,d, Fan Liub, Soo-Kyung Kimb, Ravinder Abrolb, Arthur L. DeVriese, and Lawrence M. Henlingf aDepartment of Chemistry and Biochemistry, California State University, Los Angeles, CA 90032; bDivision of Chemistry and Chemical Engineering, California Institute of Technology, Pasadena, CA 91125; cDepartment of Biological Sciences, University of Notre Dame, Notre Dame, IN 46556; dDepartment of Physics and Astronomy, California State University, Los Angeles, CA 90032; eDepartment of Animal Biology, University of Illinois at Urbana–Champaign, Urbana, IL 61801; and fBeckman Institute, California Institute of Technology, Pasadena, CA 91125 Edited by David L. Denlinger, Ohio State University, Columbus, OH, and approved April 28, 2016 (received for review January 30, 2016) The remarkable adaptive strategies of insects to extreme environ- than anhydrous trehalose in water (12); and (iii) the crystal structure ments are linked to the biochemical compounds in their body fluids. of trehalose dihydrate lacks intramolecular hydrogen bonding (13). In Trehalose, a versatile sugar molecule, can accumulate to high levels nature, crystallization or solidification of physiological solutes in body in freeze-tolerant and freeze-avoiding insects, functioning as a fluids can be lethal. As the primary sugar in insects, trehalose is mainly cryoprotectant and a supercooling agent. Antifreeze proteins (AFPs), stored in the hemolymph (14), and its production, however, can be known to protect organisms from freezing by lowering the freezing inducedtohighlevelsinthewinterhemolymphinresponsetoharsh temperature and deferring the growth of ice, are present at high environmental stresses including low temperature (15, 16). Knowledge levels in some freeze-avoiding insects in winter, and yet, paradox- of the exact level of trehalose in winter hemolymph, whether this sugar ically are found in some freeze-tolerant insects. Here, we report a crystallizes at such concentrations under fluctuating low temperatures, previously unidentified role for AFPs in effectively inhibiting treha- and the protection mechanism if it does not crystallize are essential for lose precipitation in the hemolymph (or blood) of overwintering understanding cold survival strategies and for facilitating the devel- ECOLOGY ± beetle larvae. We determine the trehalose level (29.6 0.6 mg/mL) opment of medical and industrial applications of trehalose. in the larval hemolymph of a beetle, Dendroides canadensis, and Antifreeze proteins (AFPs) bind to specific surfaces of ice demonstrate that the hemolymph AFPs are crucial for inhibiting crystals and inhibit their growth in the body fluids of cold-adapted trehalose crystallization, whereas the presence of trehalose also en- organisms in vivo (17–21). AFPs depress the freezing point of hances the antifreeze activity of AFPs. To dissect the molecular water without appreciably altering the melting point leading to a mechanism, we examine the molecular recognition between AFP difference between the melting point and the freezing point, re- and trehalose crystal interfaces using molecular dynamics simula- ferred to as thermal hysteresis (TH, a measure of antifreeze ac- tions. The theory corroborates the experiments and shows prefer- tivity). AFPs in freeze-avoiding species (they die if frozen) prevent CHEMISTRY ential strong binding of the AFP to the fast growing surfaces of the freezing in winter cold. However, they can also occur in freeze-tol- sugar crystal. This newly uncovered role for AFPs may help explain erant species (those that survive if frozen) at levels too low to the long-speculated role of AFPs in freeze-tolerant species. We pro- pose that the presence of high levels of molecules important for Significance survival but prone to precipitation in poikilotherms (their body tem- perature can vary considerably) needs a companion mechanism to Survival strategies for overwintering insects rely on the bio- prevent the precipitation and here present, to our knowledge, the chemical components in body fluids, where trehalose and an- first example. Such a combination of trehalose and AFPs also pro- tifreeze proteins (AFPs) are sometimes the best-known and vides a novel approach for cold protection and for trehalose crystal- extensively studied carbohydrate and protein components lization inhibition in industrial applications. occurring in winters in both freeze-tolerant (they can survive if frozen) and freeze-avoiding species (they die if frozen). insects | environmental stress | trehalose | crystallization | antifreeze protein AFPs are known to lower the freezing temperature and defer the growth of ice, whereas their roles in freeze-tolerant rehalose is a multifunctional nonreducing disaccharide, oc- species have long been speculated. By examining the larval Tcurring naturally in all kingdoms (1–4). In addition to being blood of a freeze-avoiding beetle, we reveal a new role for an energy and carbon source, this sugar protects cells and pro- AFPs by demonstrating that AFPs effectively inhibit trehalose teins against injuries in extreme environments (1, 2, 4), prevents crystallization. This finding provides a novel approach for osteoporosis (5), alleviates certain diseases (6), and acts as a signal cold protection and for inhibiting trehalose crystallization in molecule in plants (7). Due to its bioprotective properties, trehalose medical and industrial applications. is a potentially useful protectant of cells and proteins in numerous applications (2, 8). Its practical use, however, can be impaired by the Author contributions: X.W. and S.W. designed research; X.W. and S.W. initiated re- fact that this sugar is prone to crystallization, in particular, when its search; X.W. oversaw research; X.W., S.W., J.G.D., J.F.A., V.J., W.A.G., A.R., F.L., S.-K.K., R.A.,A.L.D.,andL.M.H.performedresearch;X.W.,S.W.,andW.A.G.analyzeddata;and aqueous solution is under fluctuating low temperatures. For exam- X.W., S.W., J.G.D., W.A.G., A.L.D., and L.M.H. wrote the paper. ple, the crystallization of trehalose dihydrate during the freeze-dry- The authors declare no conflict of interest. ing processes or from solutions at low temperatures would This article is a PNAS Direct Submission. significantly jeopardize its ability to protect biomolecules (8–10). Data deposition: The structures have been deposited at the Cambridge Crystallographic In comparison with other common sugars including sucrose, tre- Data Centre, www.ccdc.cam.ac.uk/structures (CSD reference nos. 1053435 and 1053434). halose has a high propensity to crystallize at low temperature, 1 i To whom correspondence should be addressed. Email: [email protected]. forming trehalose dihydrate crystals. This propensity is due to: ( )the 2Present address: Department of Chemistry, California State University, Dominguez Hills, solubility of trehalose in water decreases dramatically or exponen- Carson, CA 90747. tially as temperature decreases (few data at low temperature were This article contains supporting information online at www.pnas.org/lookup/suppl/doi:10. available, however) (11); (ii) trehalose dihydrate has a lower solubility 1073/pnas.1601519113/-/DCSupplemental. www.pnas.org/cgi/doi/10.1073/pnas.1601519113 PNAS Early Edition | 1of6 Downloaded by guest on September 24, 2021 produce significant antifreeze activity, causing speculation as to their role in freeze-tolerant species (16). For example, the presence of AFPs in freeze-tolerant species is thought to prevent the damage caused by ice recrystallization (21). More recently, the control of the formation of crystals in addition to ice, including nucleosides and carbohydrates by AFPs, wasreportedinvitro(22–24), inspiring further exploration of other biological functions of AFPs, in partic- ular, where dual functions have not been previously identified (15). Dendroides canadensis, a pyrochroid beetle common in eastern North America (both Canada and the United States) (25), winter as larvae in multiple instars under the loose bark of partially decomposed hardwood logs. The overwintering larvae produce a family of some 30 AFP isomers (DAFPs) that are differentially expressed in various tissues and body fluids including hemolymph, gut, urine, and epidermal cells that function to prevent inoculative freezing and promote supercooling (26, 27). The DAFPs consist of 12- and 13-mer repeating units containing highly conserved thre- onine and cysteine residues (28, 29) that form a right-handed β-solenoid structure and a relatively flat ice-binding site on one Fig. 1. Micrographs of trehalose aqueous solution and D. canadensis he- side of the repeating β-strands (30). The combination of AFP molymph during cooling and holding at low temperatures. Micrograph isoforms, purging the gut of ice nucleating bacteria, and high images of the aqueous solution of trehalose at 29.6 mg/mL (A–C) and the concentrations of glycerol and other polyols permits the larvae winter hemolymph of D. canadensis (D–F). (A and D)At−5°C.(B and E)At to avoid freezing above temperatures of approximately −18 °C to −10 °C. (C and F)At−15 °C. Trehalose precipitates were observed in the −28 °C, depending on the severity of the winter (27). The hemo- trehalose aqueous solution but not D. canadensis hemolymph. lymph of D. canadensis was studied as a model system in this work. Results
Load more

Recommended publications
  • Distribution and Functional Characterisation of Antifreeze Proteins in Polar Diatoms
    Living inside Sea Ice - Distribution and Functional Characterisation of Antifreeze Proteins in Polar Diatoms Dissertation zur Erlangung des akademischen Grades eines Doktors der Naturwissenschaften - Dr. rer. Nat. - am Fachbereich 2 (Biologie/Chemie) der Universit¨atBremen vorgelegt von Christiane Uhlig Bremen Oktober, 2011 1. Pr¨ufer: Prof. Kai Bischof 2. Pr¨ufer: Prof. Ulrich Bathmann F¨urmeine Mutter Monika Was Menschen in die Polargebiete trieb, war die Macht des Unbekannten ¨uber den men- schlichen Geist. Sie treibt uns zu den verborgenen Kr¨aftenund Geheimnissen der Natur, hinab in die unermesslich kleine mikroskopische Welt und desgleichen hinaus in die uner- forschten Weiten des Universums. Sie l¨asstuns keine Ruhe, bis wir den Planeten, auf dem wir leben, von der tiefsten Tiefen des Ozeans bis zu den h¨ochsten Schichten der Atmosph¨arekennen. Fridtjof Nansen Danksagung Ich danke Prof. Ulrich Bathmann und Prof. Kai Bischof f¨urdie Begutachtung dieser Arbeit. Prof. Rudolf Amann danke ich, dass er sich kurzfristig bereit erkl¨arthat die Aufgabe des 3. Pr¨uferzu ¨ubernehmen. Bei Prof. Kai Bischof und Andreas Krell bedanke ich mich f¨urdie Hilfe zur Einwerbung des Stipendiums, welches diese Arbeit ¨uberhaupt erst erm¨oglicht hat. Der Studienstiftung des deutschen Volkes danke ich f¨ur die finanzielle Unterst¨utzung. Ich bedanke mich ganz besonders bei der Meereis-Gruppe, die mehr ist als nur eine Ar- beitsgruppe. Besonders danke ich Gerhard Dieckmann, dass ich in Deiner Arbeitsgruppe meine Arbeit durchf¨uhrendurfte und f¨ur Deine Unterst¨utzungin allen m¨oglichen organ- isatorischen und pers¨onlichen Dingen. Klaus Valentin danke ich f¨urdie Unterst¨utzung, kreativen Titelvorschl¨ageund den Einsatz daf¨ur,dass ich noch eine Weile am AWI bleiben kann.
    [Show full text]
  • Effects of Antifreeze Protein III on Sperm Cryopreservation of Pacific Abalone, Haliotis Discus Hannai
    International Journal of Molecular Sciences Article Effects of Antifreeze Protein III on Sperm Cryopreservation of Pacific Abalone, Haliotis discus hannai Shaharior Hossen 1 , Md. Rajib Sharker 1,2, Yusin Cho 1, Zahid Parvez Sukhan 1 and Kang Hee Kho 1,* 1 Department of Fisheries Science, College of Fisheries and Ocean Sciences, Chonnam National University, 50 Daehak-ro, Yeosu 59626, Jeonnam, Korea; [email protected] (S.H.); [email protected] (M.R.S.); [email protected] (Y.C.); [email protected] (Z.P.S.) 2 Department of Fisheries Biology and Genetics, Faculty of Fisheries, Patuakhali Science and Technology University, Patuakhali 8602, Bangladesh * Correspondence: [email protected]; Tel.: +82-616-597-168; Fax: +82-616-597-169 Abstract: Pacific abalone (Haliotis discus hannai) is a highly commercial seafood in Southeast Asia. The aim of the present study was to improve the sperm cryopreservation technique for this valuable species using an antifreeze protein III (AFPIII). Post-thaw sperm quality parameters including motility, acrosome integrity (AI), plasma membrane integrity (PMI), mitochondrial membrane potential (MMP), DNA integrity, fertility, hatchability, and mRNA abundance level of heat shock protein 90 (HSP90) were determined to ensure improvement of the cryopreservation technique. Post-thaw motility of sperm cryopreserved with AFPIII at 10 µg/mL combined with 8% dimethyl sulfoxide (DMSO) (61.3 ± 2.7%), 8% ethylene glycol (EG) (54.3 ± 3.3%), 6% propylene glycol (PG) (36.6 ± 2.6%), or 2% glycerol (GLY) (51.7 ± 3.0%) was significantly improved than that of sperm cryopreserved without AFPIII. Post-thaw motility of sperm cryopreserved with 2% MeOH and 1 µg/mL of AFPIII was also improved than that of sperm cryopreserved without AFPIII.
    [Show full text]
  • Iiillllllllli'lllll | US005627051A United States Patent [191 [11] Patent Number: 5,627,051 Duman [45] Date of Patent: May 6, 1997
    llilll|||l|l|||||ll||||||i|lllllllllllllllllllllllllllll.nIiillllllllli'lllll | US005627051A United States Patent [191 [11] Patent Number: 5,627,051 Duman [45] Date of Patent: May 6, 1997 [54] NUCLEIC ACID SEQUENCES ENCODING LG. Duman et al.. ‘Thermal hysteresis proteins”. Advances DENDROIDES ANTIFREEZE PROTEINS in Low Temperature Biology, vol. 2. pp. 131-182, (1993). [75] Inventor: John G. Duman. South Bend. Ind. D. Tursman et al., “Cryoprotective eifects of Thermal Hys teresis Protein on Survivorship of Frozen Gut Cells from the [73] Assignee: University of Notre Dame du Lac, Freeze Tolerant Centipede Lithobius for?catus”, Journal of Notre Dame, Ind. Experimental Zoology. vol. 272, pp. 249-257 (1995). D.W. Wu et al., “Activation of antifreeze proteins from [21] Appl. No.: 485,359 larvae of the beetle Dendroides canadensis”, Comp. Physiol. [22] Filed: Jun. 7, 1995 B, vol. 161, pp. 279-283 (1991). [51] Int. Cl.6 ........................... .. C12P 21/02; C07H 21/04 D.W. Wu et al., “Puri?cation and characterization of anti [52] US. Cl. .. 435/69.1; 536/235; 536/2431 freeze proteins from larvae of the beetle Dendroides [58] Field of Search .............................. .. 435/3201, 69.1; canadensis”, Comp. Physiol. B, vol. 161, pp. 271-278 536/235. 24.31 (1991). [56] References Cited Primary Examiner—Dian C. Jacobson PUBLICATIONS Assistant Examiner-Kawai Lau J.G. Duman et al., “Hemolymph proteins involved in insect Attorney, Agent, or Firm—Barnes & Thomburg subzero tolerance: Ice nucleators and antifreeze proteins”, In Insects at Low Temperatures, Chapman and Hall (N .Y.), pp. [57] ABSTRACT 94-127 (1991). The present invention is directed to nucleic acid sequences D.W.
    [Show full text]
  • A New Genus of Fire-Colored Beetles (Coleoptera: Pyrochroidae: Pyrochroinae) from the Sunda Shelf, with a Key to the Three Species Daniel K
    University of Nebraska - Lincoln DigitalCommons@University of Nebraska - Lincoln Center for Systematic Entomology, Gainesville, Insecta Mundi Florida 2014 Sundapyrochroa: A new genus of Fire-Colored Beetles (Coleoptera: Pyrochroidae: Pyrochroinae) from the Sunda Shelf, with a key to the three species Daniel K. Young University of Wisconsin - Madison Follow this and additional works at: http://digitalcommons.unl.edu/insectamundi Young, Daniel K., "Sundapyrochroa: A new genus of Fire-Colored Beetles (Coleoptera: Pyrochroidae: Pyrochroinae) from the Sunda Shelf, with a key to the three species" (2014). Insecta Mundi. 846. http://digitalcommons.unl.edu/insectamundi/846 This Article is brought to you for free and open access by the Center for Systematic Entomology, Gainesville, Florida at DigitalCommons@University of Nebraska - Lincoln. It has been accepted for inclusion in Insecta Mundi by an authorized administrator of DigitalCommons@University of Nebraska - Lincoln. INSECTA MUNDI A Journal of World Insect Systematics 0341 Sundapyrochroa: A new genus of Fire-Colored Beetles (Coleoptera: Pyrochroidae: Pyrochroinae) from the Sunda Shelf, with a key to the three species Daniel K. Young Department of Entomology 445 Russell Laboratories University of Wisconsin Madison, Wisconsin 53706-1598 USA Date of Issue: January 31, 2014 CENTER FOR SYSTEMATIC ENTOMOLOGY, INC., Gainesville, FL Daniel K. Young Sundapyrochroa: A new genus of Fire-Colored Beetles (Coleoptera: Pyrochroidae: Pyrochroinae) from the Sunda Shelf, with a key to the three species Insecta Mundi 0341: 1-18 ZooBank Registered: urn:lsid:zoobank.org:pub:994D7E0D-D7DF-49A3-9A25-25EE0B3D7F22 Published in 2014 by Center for Systematic Entomology, Inc. P. O. Box 141874 Gainesville, FL 32614-1874 USA http://centerforsystematicentomology.org/ Insecta Mundi is a journal primarily devoted to insect systematics, but articles can be published on any non-marine arthropod.
    [Show full text]
  • Structure and Application of Antifreeze Proteins from Antarctic Bacteria Patricio A
    Muñoz et al. Microb Cell Fact (2017) 16:138 DOI 10.1186/s12934-017-0737-2 Microbial Cell Factories RESEARCH Open Access Structure and application of antifreeze proteins from Antarctic bacteria Patricio A. Muñoz1*, Sebastián L. Márquez1,2, Fernando D. González‑Nilo3, Valeria Márquez‑Miranda3 and Jenny M. Blamey1,2* Abstract Background: Antifreeze proteins (AFPs) production is a survival strategy of psychrophiles in ice. These proteins have potential in frozen food industry avoiding the damage in the structure of animal or vegetal foods. Moreover, there is not much information regarding the interaction of Antarctic bacterial AFPs with ice, and new determinations are needed to understand the behaviour of these proteins at the water/ice interface. Results: Diferent Antarctic places were screened for antifreeze activity and microorganisms were selected for the presence of thermal hysteresis in their crude extracts. Isolates GU1.7.1, GU3.1.1, and AFP5.1 showed higher thermal hysteresis and were characterized using a polyphasic approach. Studies using cucumber and zucchini samples showed cellular protection when samples were treated with partially purifed AFPs or a commercial AFP as was determined using toluidine blue O and neutral red staining. Additionally, genome analysis of these isolates revealed the presence of genes that encode for putative AFPs. Deduced amino acids sequences from GU3.1.1 (gu3A and gu3B) and AFP5.1 (afp5A) showed high similarity to reported AFPs which crystal structures are solved, allowing then generating homology models. Modelled proteins showed a triangular prism form similar to β-helix AFPs with a linear distribution of threonine residues at one side of the prism that could correspond to the putative ice binding side.
    [Show full text]
  • Replacement of the Antifreeze-Like Domain of Human N-Acetylneuraminic Acid Phosphate Synthase with the Mouse Antifreeze-Like
    Replacement of the antifreeze-like domain of human N-acetylneuraminic acid phosphate synthase with the mouse antifreeze-like domain impacts both N-acetylneuraminic acid 9-phosphate synthase and 2-keto-3-deoxy-D-glycero-D- galacto-nonulosonic acid 9-phosphate synthase activities Marshall Louis Reaves1,2, Linda Carolyn Lopez1 & Sasha Milcheva Daskalova1,* 1The Biodesign Institute, Arizona State University, Tempe Arizona, 85287, 2Department of Molecular Biology, Princeton University, Princeton, New Jersey 08544, USA Human NeuNAc-9-P synthase is a two-domain protein with In prokaryotes, the final stage of formation of N-ace- ability to synthesize both NeuNAc-9-P and KDN-9-P. Its tyl-D-neuraminic acid (NeuNAc) the most common sialic mouse counterpart differs by only 20 out of 359 amino acids acid in nature involves condensation of N-Acetyl-D-mannos- but does not produce KDN-9-P. By replacing the AFL domain amine (ManNAc) with phosphoenol pyruvate (PEP). The proc- of the human NeuNAc-9-P synthase which accommodates 12 ess, when irreversible, is catalyzed by the enzyme NeuNAc of these differences, with the mouse AFL domain we examined synthase (E.C. 4.1.3.19). The first bacterial gene, neuB gene, its importance for the secondary KDN-9-P synthetic activity. coding for the E. coli enzyme was identified in 1995 (2) and The chimeric protein retained almost half of the ability of the this later allowed overexpression and purification of sufficient human enzyme for KDN-9-P synthesis while the NeuNAc-9-P amount of protein for detailed characterization (3). Using the production was reduced to less than 10%.
    [Show full text]
  • Enhancement of Insect Antifreeze Protein Activity by Solutes of Low Molecular Mass
    The Journal of Experimental Biology 201, 2243–2251 (1998) 2243 Printed in Great Britain © The Company of Biologists Limited 1998 JEB1557 ENHANCEMENT OF INSECT ANTIFREEZE PROTEIN ACTIVITY BY SOLUTES OF LOW MOLECULAR MASS NING LI, CATHY A. ANDORFER AND JOHN G. DUMAN* Department of Biological Sciences, University of Notre Dame, Notre Dame, IN 46556, USA *Author for correspondence (e-mail: [email protected]) Accepted 20 May; published on WWW 14 July 1998 Summary Antifreeze proteins (AFPs) lower the non-equilibrium Glycerol is the only one of these enhancing solutes that is freezing point of water (in the presence of ice) below the known to be present at these concentrations in melting point, thereby producing a difference between the overwintering D. canadensis, and therefore the freezing and melting points that has been termed thermal physiological significance of most of these enhancers is hysteresis. In general, the magnitude of the thermal unknown. The mechanism(s) of this enhancement is also hysteresis depends upon the specific activity and unknown. concentration of the AFP. This study describes several low- The AFP used in this study (DAFP-4) is nearly identical molecular-mass solutes that enhance the thermal hysteresis to previously described D. canadensis AFPs. The mature activity of an AFP from overwintering larvae of the beetle protein consists of 71 amino acid residues arranged in six 12- Dendroides canadensis. The most active of these is citrate, or 13-mer repeats with a consensus sequence consisting of which increases the thermal hysteresis nearly sixfold from Cys-Thr-X3-Ser-X5-X6-Cys-X8-X9-Ala-X11-Thr-X13, where 1.2 °C in its absence to 6.8 °C.
    [Show full text]
  • Antifreeze Protein Improves the Cryopreservation Efficiency of Hosta Capitata by Regulating the Genes Involved in the Low-Temper
    horticulturae Study Protocol Antifreeze Protein Improves the Cryopreservation Efficiency of Hosta capitata by Regulating the Genes Involved in the Low-Temperature Tolerance Mechanism Phyo Phyo Win Pe 1,2,†, Aung Htay Naing 3,† , Chang Kil Kim 3,* and Kyeung Il Park 1,* 1 Department of Horticulture and Life Science, Yeungnam University, Gyeongsan 38541, Korea; [email protected] 2 Department of Horticulture, Yezin Agricultural University, Nay Pyi Taw 15013, Myanmar 3 Department of Horticulture, Kyungpook National University, Daegu 41566, Korea; [email protected] * Correspondence: [email protected] (C.K.K.); [email protected] (K.I.P.) † Phyo Phyo Win Pe and Aung Htay Naing equally contributed to this work. Abstract: In this study, whether the addition of antifreeze protein (AFP) to a cryopreservative solution (plant vitrification solution 2 (PVS2)) is more effective in reducing freezing injuries in Hosta capitata than PVS2 alone at different cold exposure times (6, 24, and 48 h) is investigated. The upregulation of C-repeat binding factor 1 (CBF1) and dehydrin 1 (DHN1) in response to low temperature was observed in shoots. Shoots treated with distilled water (dH2O) strongly triggered gene expression 6 h after cold exposure, which was higher than those expressed in PVS2 and PVS2+AFP. However, 24 h after cold exposure, gene expressions detected in dH2O and PVS2 treatments were similar and Citation: Pe, P.P.W.; Naing, A.H.; higher than PVS2 + AFP. The expression was highest in PVS2+AFP when the exposure time was Kim, C.K.; Park, K.I. Antifreeze extended to 48 h. Similarly, nitric reductase activities 1 and 2 (Nia1 and Nia2) genes, which are Protein Improves the responsible for nitric oxide production, were also upregulated in low-temperature-treated shoots, Cryopreservation Efficiency of Hosta as observed for CBF1 and DHN1 expression patterns during cold exposure periods.
    [Show full text]
  • The Physiology of Cold Hardiness in Terrestrial Arthropods*
    REVIEW Eur. J. Entomol. 96: 1-10, 1999 ISSN 1210-5759 The physiology of cold hardiness in terrestrial arthropods* L auritz S0MME University of Oslo, Department of Biology, P.O. Box 1050 Blindern, N-0316 Oslo, Norway; e-mail: [email protected] Key words. Terrestrial arthropods, cold hardiness, ice nucleating agents, cryoprotectant substances, thermal hysteresis proteins, desiccation, anaerobiosis Abstract. Insects and other terrestrial arthropods are widely distributed in temperate and polar regions and overwinter in a variety of habitats. Some species are exposed to very low ambient temperatures, while others are protected by plant litter and snow. As may be expected from the enormous diversity of terrestrial arthropods, many different overwintering strategies have evolved. Time is an im­ portant factor. Temperate and polar species are able to survive extended periods at freezing temperatures, while summer adapted species and tropical species may be killed by short periods even above the freezing point. Some insects survive extracellular ice formation, while most species, as well as all spiders, mites and springtails are freeze intoler­ ant and depend on supercooling to survive. Both the degree of freeze tolerance and supercooling increase by the accumulation of low molecular weight cryoprotectant substances, e.g. glycerol. Thermal hysteresis proteins (antifreeze proteins) stabilise the supercooled state of insects and may prevent the inoculation of ice from outside through the cuticle. Recently, the amino acid sequences of these proteins have been revealed. Due to potent ice nucleating agents in the haemolymph most freeze tolerant insects freeze at relatively high temperatures, thus preventing harmful effects of intracellular freezing.
    [Show full text]
  • Supporting Information
    Supporting Information Deng et al. 10.1073/pnas.1007883107 Fig. S1. Nucleotide sequence alignment of the C-terminal domain coding exon (exon6) of Ld sialic acid synthase (SAS)-A and LdSAS-B and exon2 of three typical antifreeze protein (AFP)III genes, LdψAFPIII, LdAFPIII-1, and LdAFPIII-2, from the Lycodichthys dearborni AFPIII locus. Among AFPIII genes, LdψAFPIII shares the greatest sequence similarity with the LdSAS genes, including having six additional nucleotides (shown in red) not present in the other two AFPIII genes, suggesting that LdψAFPIII is the earliest member of the AFPIII gene family. Asterisks indicate identical nucleotides between the six sequences, and the asterisks in red indicate identical nucleotides shared between LdψAFPIII and the LdSAS genes. The stop codon (TGA for SAS and TAG for AFPIII) is underlined. Fig. S1 (PDF) Fig. S2. Sequence alignments of LdSAS-A, LdSAS-B, and LdψAFPIII, the putative primitive AFPIII gene members from L. dearborni.(A) Nucleotide sequence alignment and deduced amino acid sequence of LdSAS-A and LdSAS-B. The proximal 5′ flanking sequences (∼600 nt) of the two genes share no sequence similarity and thus, are not homologous. The locations of the six exons are labeled, and exon sequences and translated amino acids are bold. Amino acidsand codons of LdSAS-B that differ from LdSAS-A are shown in blue. (B) Nucleotide sequence alignment of the homologous regions between LdSAS-B and LdψAFPIII. The proximal 5′ flanking regions of the two genes are homologous. The color highlighted LdSAS-B sequence regions (in the ancestral LdSAS-B) gave rise to the AFPIII gene.
    [Show full text]
  • Animal Ice-Binding (Antifreeze) Proteins and Glycolipids: an Overview with Emphasis on Physiological Function John G
    © 2015. Published by The Company of Biologists Ltd | The Journal of Experimental Biology (2015) 218, 1846-1855 doi:10.1242/jeb.116905 REVIEW Animal ice-binding (antifreeze) proteins and glycolipids: an overview with emphasis on physiological function John G. Duman* ABSTRACT Storey and Storey, 2012, 2013). However, certain adaptations have Ice-binding proteins (IBPs) assist in subzero tolerance of multiple evolved in widely divergent organisms, for example, antifreeze cold-tolerant organisms: animals, plants, fungi, bacteria etc. IBPs proteins (AFPs) and other ice-binding proteins (IBPs), as well as include: (1) antifreeze proteins (AFPs) with high thermal hysteresis antifreeze glycolipids (AFGLs). antifreeze activity; (2) low thermal hysteresis IBPs; and (3) ice- AFPs were first discovered by DeVries in Antarctic marine fish nucleating proteins (INPs). Several structurally different IBPs have (DeVries and Wohlschlag, 1969; DeVries, 1971), where, as their evolved, even within related taxa. Proteins that produce thermal name implies, they function to prevent freezing. Since then, AFPs hysteresis inhibit freezing by a non-colligative mechanism, whereby have been identified in numerous other organisms, such as freeze- they adsorb onto ice crystals or ice-nucleating surfaces and prevent avoiding insects and other terrestrial arthropods. However, proteins further growth. This lowers the so-called hysteretic freezing point with similar, but considerably lesser, antifreeze (thermal hysteresis below the normal equilibrium freezing/melting point, producing a or TH) activities have been found in freeze-tolerant species, where difference between the two, termed thermal hysteresis. True AFPs they do not prevent organismal freezing, but instead function to with high thermal hysteresis are found in freeze-avoiding animals control the site and temperature of ice formation, ice crystal structure (those that must prevent freezing, as they die if frozen) especially and rate of freezing.
    [Show full text]
  • Biodiversity Research and Innovation in Antarctica and the Southern Ocean
    bioRxiv preprint doi: https://doi.org/10.1101/2020.05.03.074849; this version posted May 3, 2020. The copyright holder for this preprint (which was not certified by peer review) is the author/funder, who has granted bioRxiv a license to display the preprint in perpetuity. It is made available under aCC-BY 4.0 International license. 1 Biodiversity Research and Innovation in Antarctica and the 2 Southern Ocean 3 2020 4 Paul Oldham and Jasmine Kindness1 5 Abstract 6 This article examines biodiversity research and innovation in Antarctica and the Southern 7 Ocean based on a review of 150,401 scientific articles and 29,690 patent families for 8 Antarctic species. The paper exploits the growing availability of open access databases, 9 such as the Lens and Microsoft Academic Graph, along with taxonomic data from the Global 10 Biodiversity Information Facility (GBIF) to explore the scientific and patent literature for 11 the Antarctic at scale. The paper identifies the main contours of scientific research in 12 Antarctica before exploring commercially oriented biodiversity research and development 13 in the scientific literature and patent publications. The paper argues that biodiversity is not 14 a free good and must be paid for. Ways forward in debates on commercial research and 15 development in Antarctica can be found through increasing attention to the valuation of 16 ecosystem services, new approaches to natural capital accounting and payment for 17 ecosystem services that would bring the Antarctic, and the Antarctic Treaty System, into 18 the wider fold of work on the economics of biodiversity.
    [Show full text]